vernoniosides d and e, two novel saponins from vernonia amygdalzna

Vernonia amygdalina Del. (Com- positae) is a small tree that grows through- out tropical Africa. The leaves are used as a vegetable and spice in West ...
1 downloads 0 Views 434KB Size
Journal of Natural Products Vol. 58, NO.9, pp. 1438-1443, September 1995

1438

VERNONIOSIDES D AND E, TWO NOVEL SAPONINS FROM VERNONIA AMYGDALZNA GODWIN IGILE,’

Department

WIESeAW oLESZEK,* MARIAN JURZYSTA,

of Biochemistry, Institute of Soil Science and Plant Cultivation, 24-1 00 Pulawy, Poiand RITA

AQUINO,NLNZLATINA DE TOMMASI, and COSIMO PIZU

Dipartimento di Chimica delle Sostanze Naturali, Universita “Federico11,” via D.Montesano, 80131 Napoli, Italy ABSTRACT.-TWO new stigmastane-type steroid glycosides, vemoniosides D E l ] and E [2], have been isolated from the leaves of Vernonia amyguklim, along with the known vemonioside A,. Vemonioside D 111 was the most abundant glycoside obtained. The chemical structures of 1 and 2 were elucidated using a combination of spectroscopic techniques.

Vernonia amygdalina Del. (Compositae) is a small tree that grows throughout tropical Africa. The leaves are used as a vegetable and spice in West Africa, particularly Nigeria. The leaves are also extracted with alcohol, or with H,O (hot or cold), as medicinals that have extensive therapeutic applications including antimalarial, antihelminthic, and antianorexic activities, as well as in gynecological applications (1). In southern Africa, an apparently sick chimpanzee is reported to have chewed and extracted juice from tissues of this plant to regain its health (2). Several secondary metabolites have been isolated from the leaves of V. amygdalina, including antimalarial and insect antifeedant sesquiterpene lactones (1,3,4),bitter and non-bitterstigmastanetype glycosides (5-lo), and flavones (11).

In a continuation of our investigation into the bioactive constituents of Vernonia amygdulina, we describe herein the isolation and chemical characterization of two new stigmastane-type steroidal glycosides, as well as vernonioside A, that was reported previously by Jisaka et al. (7). The three compounds isolated from the MeOH extract of V.amygdalina,comprised the glycosides, 1, 2, and vernonioside A,. Glucose was the only sugar identified by tlc after enzymatic hydrolysis of each glycoside. All three substances were shown to contain a hexose unit by fabms, which was identified as P-D-glucopyranoside by ‘H- and 13Cnmr data (Table 1). Nmr data led to the identification of the aglycone moiety of these compounds as a C-29 stigmastane-type sterol. These

2 8 2 9

HH

” I , -&

OH

1 ’Present address: Department of Biochemistry, University of Ibadan, Ibadan, Nigeria.

2

September 19951

Igile et a1.: Saponins from Vernonia

1439

Compound

1'

Position

1 ........................ 2

........................

3 ........................ 4 ........................ 5 ........................ 6 ........................ 7 ........................ 8 ........................ 9 ........................ 10 . . . . . . . . . . . . . . . . . . . . . . . 11 ....................... 12 . . . . . . . . . . . . . . . . . . . . . . . 13 . . . . . . . . . . . . . . . . . . . . . . . 14 . . . . . . . . . . . . . . . . . . . . . . . 15 . . . . . . . . . . . . . . . . . . . . . . . 16 . . . . . . . . . . . . . . . . . . . . . . . 17 . . . . . . . . . . . . . . . . . . . 18

19

20 . . . . . . . . . . . . . . . . . . . . . . . 21 . . . . . . . . . . . . . . . . . . . . . . . 22 23 . . . . . . . . . . . . . . . . . . . . . . . 24 25 . . . . . . . . . . . . . . . . . . . . . . . 26 27 ....................... 28 . . . . . . . . . . . . . . . . . . . . . . . 29 . . . . . . . . . . . . . . . . . . . . . . . OCOMe . . . . . . . . . . . . . . . . . . . 1' . . . . . . . . . . . . . . . . . . . . . . . . 2' . . . . . . . . . . . . . . . . . . . . . . . . 3' . . . . . . . . . . . . . . . . . . . . . . . . 4' . . . . . . . . . . . . . . . . . . . . . . . . 5' . . . . . . . . . . . . . . . . . . . . . . . . 6' . . . . . . . . . . . . . . . . . . . . . . . .

a 1.05

P a

P a a

P aandp

a

B

1.45 1.95 1.60 3.75 2.00 1.51 1.30 1.88 5.44, br s 5.52 br d, J=6 1.42 2.33 2.53 1.80-2.20 4.25, br m 1.84 0.59, s 0.91, s 2.36, br m 5.31 d, J=6 4.90' 4.40b 2.12, br m 1.03, d, J=6 3.50, dd, J=8.9, 7 4.03, dd, J=8.5,6.1 1.36, s 2.05 4.40b 3.22 3.48 3.40 3.36 3.87 3.70

1

2

35.00

30.97

30.55

30.55

78.41 35.94

78.86 35.91

40.13 30.98 121.92 136.83 145.29 37.10 119.00 40.70

39.90 30.98 122.14 136.91 145.18 34.72 119.22 40.46

44.5 1 49.55 36.00 77.40 59.33 13.89 19.83 53.56 104.96 85.17 86.01 88.28 41.70 10.39 73.69

43.61 50.06 37.07 70.03 56.96 14.24 19.85 33.00 12.98 47.80 80.88 7 1.00 63.93 14.25 26.85

118.23 2 1.43

71.00 28.35 21.51 172.83 102.35 75.13 77.86 7 1.67 78.09 62.80

102.12 75.13 77.86 7 1.67 78.09 62.80

'Assignments confirmed by COSY. HETCOR. and COLOC experiments. bOverlappedsignals. 'Under D. 0 signal.

three glycosides also showed similar patterns in their uv spectra. having three absorption maxima at 234.241. and 25 1 nm. indicating the presence of a chro-

mophoric conjugated A'*'"' diene function in the aglycone (7.12) . This chromophore has been shown to be a characteristic structural feature of stigmastane-

1440

Journal of Natural Products

type saponins in V. amygdulina, and together with their particular side-chain, may have some biogenetic and chemotaxonomic significance. The lsims of compound 1 showed clearly quasi-molecular ions at mlz 663 {M-HI-and665 {M+H]+,in thenegative- and positive-ion modes, respectively. The eims spectral data of its aglycone, obtained by enzymatic hydrolysis, indicated a peak at mlz 488, considered to be a [M-CH3]+ ion, calcd for CZ9H4,0,(mlz 502). These ms data, together with 13Cnmr and DEPT 13C-nmranalysis, showed the molecular formula of compound 1 to be C,,H,,O,,. Additionally, the eims spectrum of the aglycone showed a base peak at mlz 268, consistent with the composition EM-side-chain-H,OI+. This indicated that the steroid-cyclic system of compound 1 had a mol wt of 286 daltons {C19H26027, identical to that of a series of vernoniosides reported previously (7). It was ascribableto aA739(11) steroidal nucleus with two hydroxyl groups at C-3P and C16a by 13C-nmrspectroscopy,as the data for C-1 to C- 19were very similar to those reported for vernonioside A, (6). In fact, the chemical shifts of C-2 (30.55 ppm), C-3 (78.41 pprn), and C-4 (35.94 pprn) revealed the presence of a P-oriented glucosyl moiety at C-3 by comparison with the same signals of the aglycone. Chemical shifts of C-16 (77.40 ppm), C15 (36.00 ppm), and C-17 (59.33 ppm), which were somewhat different from the analogous signals of vernonioside A,, but close to those of vernonioside A, (7), suggested that the second hydroxyl group was at C-16 and was a-orientated in compound 1,as in vernonioside A,. Having established this information, the presence of an unusually oxygenated side-chain with the compositionCl,H150, was evident, whose structure was established by the extensive use of 1D and 2D n m r techniques. A combination of COSY and HETCOR experiments showed the following connectivities: C-2 3 4 2 2 4 2 0 4 - 17-C- 1 6 4 -15 - C - 14, and C-20-

Wol. 58, No. 9

C-21. The presence of an unusual HC(CH,O)-CH3 group, instead of the terminal isopropyl group typical of other vernoniosides, was shown by the 'H-nmr coupling of C-25 (CH) with both C-26 (Me) and C-27 (CH,O-) in the COSY spectrum. The chemical shifts of C-2 1 (104.96 ppm) and H-21 (5.31 ppm) suggested that C-21 is involved in a hemiacetal linkage with C-23. Nmr data of C-20 ('H, 6 2.3 t, 13C,6 53.56), C-22 ('H, 6

4.90,13C,S84.85)andC-23('H,S4.40, 13 C, 6 86.01) demonstrated that they constituted one angular methine and two hydroxymethines, respectively. A quaternary l3C-nrnr signal at 118.23 pprn together with a second Me signal (13C, 21.43 ppm, 'H, 1.36, s) proved the formation of a ketal at C-28 and the complete cyclization of the side-chain of 1. Therefore, the remaining quaternary C signal at 88.28 pprn was assigned to the hydroxylated C-24 position. To confirm the proposed structure of the side-chain of compound 1,a COLOC nmr experiment was conducted, in which significant cross-peaks were seen between the ketal C-28 (118.23 ppm) and the chemical shifts of Me-29, H,-27, and H23; between the hemiacetal C-2 1(104.96 ppm) and H-22; between C-17 (59.33 ppm) and Me-18; between the quaternary hydroxylated C-24 (88.28ppm) and H-20, as well as between the carbinyl carbonC-22 (85.17 ppm)andH-23.The relative stereochemistry at the asymmetric carbon of the side-chain was ascertained by evaluating nOe effects. A nOe effect was recorded for both H-25 and H2 1 by irradiation of Me-29. Noes were also recorded for H-22 by irradiating Me26,aswellasforbothMe-19andH-20 by irradiation of Me-18. Finally, these observations confirmed the correctness of the structure proposed for 1.The trivial name vernonioside D is proposed for 1. Although the occurrence of stigmastanetype glycosides which form a hemiacetal a t C-21 or a ketal at C-28 (i.e.,

September 19951

Igile et al. : Saponins from Vernonia

vernoniosides B, and B,) has been reported in Vernonia species (7,13), vernonioside D is the first example of a glycoside with complete cyclization of the side-chain. Compound 2 in the negative lsims spectrum revealed a molecular ion at mlz 677, together with ions at mlz 633 and 5 15, corresponding to the loss of an acetyl function and glucose from the parent ion, respectively. Thus, the molecular formula, deduced also by I3C- and DEPT 13 C-nmr data was C37H58011. The eims spectrum of the aglycone showed a molecular ion at mlz 472 and some additional ions (mlz 268 and 31 l),indicating a steroid system similar to that found in 1.The ion at mlz 472 was interpreted as being a quasi-molecular peak resulting from the loss of an acetyl function from the aglycone molecule. The presence of an acetyl group was confirmed by signals at21.51and 172.83ppminthe13C-nmr spectrum of 2. The nmr spectrum also demonstrated (Table 1) that 2 possesses the same carbon skeletal structure of the sterol framework from C-1 to C-19 of compound 1.A difference was in the porientation of the OH group at C-16. In fact, C-16 and C-17 resonated at higher field whereas C-15 resonated at lower field than in 1 (Table 1).These observations are in good agreement with the data reported for vernoniosides A, and A, (6) and with some other steroids (14). Consequently, the acetyl group was located in the side-chain. The 'H-nmr spectrum of 2 showed the presence of two tertiary methyls (1.45 and 1.46ppm) and two secondary methyl signals (6 1.67, d,J=5.5 Hz and 1.16, d, J=6.0 Hz) as well as a proton (6 5.28) geminal to an OCOCH, group. The tertiary methyls linked to a carbinol (C-25) were assigned to C-26 and C-27 of a terthydroxypropyl group. A Me resonating at 6 1.67, which was coupled to a proton at 6 3.12, was placed at C-28 (63.93 ppm) forming an epoxidewith C-24 (7 1.O ppm), and the remaining Me at 6 1.16

1441

was assigned to C-21 of an open sidechain (combination of 'H-IH COSY and 'H-',C HETCOR). A series of selective decoupling experiments starting from the Me-21 signal suggested the partial sequence H32 1-H-20-H2-22-H-23. The acetylated hydroxyl group was confirmed to be at C23 by the relevant chemical shift in the 13 C-nmr spectrum (CH, 80.28 ppm), as well as by the chemical shift, the form of the signal, and the coupling pattern of H23 in the 'H-nmr spectrum ( l H , 6 5.28, t). From all of these data the structure of compound 2 was confirmed, for which the trivial name vernonioside E has been given. Vernonioside A,, on enzymatic hydrolysis, produced an aglycone showing an eims molecular ion at mlz 468 [M}', calcd for C,,H,O,. The lsims spectrum indicated the mol wt of the glycoside as 630 daltons. These data were similar to the results reported previously for vernonioside A, (6). This identity was further confirmed by 'H- and I3C-nmr data, which were in good agreement with those reported in the literature (6). Vernonioside D 117 isolated in the present work was a major compound with a concentration of 0.45% (dry wt). As shown in our previous experiments described elsewhere@),feedingmice with diets containing 25% V. amygdalina leaves, an alcoholic extract, a mixture of crude saponins, or vernonioside D for 14 days influenced animal performance. These treatments caused significant reduction in body weight gain and increased urine and fecal output. At necropsy, the liver weights and liver and plasma cholesterol levels were significantly reduced, and saponins were proved to be responsible for these effects. These experiments indicate that the chemistry and biological activity of V. amygdalina saponins should be more closely investigated and that their level of safe utilization should be definitively established.

1442

Journal of Natural Products

Wol. 58, No. 9

(RP-18, Lichroprep, 15-25 pin, Baker) glass cc (42 cmX 3.5 cm,Arnicon)elutedwith 50% MeOH. GENERALEXPERIMENTALPROCEDURES.-UV The semi-purified fraction was then purified by spectraweremeasuredinMeOHusingaBeckman reversed-phase (C,,, Europrep 60-20; 15-25 pm, DU-68 spectrophotometer. For nmr, Bruker WHKnauer, steel column) and normal-phase (Si gel 250 Spectroscopin and Bruker AMX-500 spec60, panicle size 15-25 pm, Merck, steel column) hplc using Type 64 pump (Knauer). In the retrometers equipped with a Bruker X-32 comversed-phase purification, a solvent gradient of puter and UXNMR software package were used. 40-70% MeOH was employed (Beckman Inc., Two-dimensional COSY nmr experiments were Nyon, Switzerland). Cornpound 1 was purified measured by employing the conventional pulse using a Si gel column, eluting with CHC1,sequence. The COSY spectra were obtained using a data set (tlXt2) of 1024x1024 points for a CH,OH-H,O (65:14:1). The pure fraction was spectral width of 1165 Hz (relaxation delay 1 taken to dryness under reduced pressure and presec). The data matrix was processed using an cipitated from a CH,OH-H,O (1:3) mixture. The unshifted sine bell window function, following precipitate was lyophilized to afford a white amortransformation to give a magnitude spectrum phous powder (2.7 g); R, 0.38 (SI); uv A max with symmetrization (digital resolution in both (MeOH)234,241,251 nm;'H-and"C-nmrdata, F, and F, dimensions 1.13 Hzlpt). The HETCOR see Table 1; lsims (NBA) rnlz (positive) 665 [MSH]', 503 [M-glc+H]-, 467, 431, 267; nmr experiments were performed on a 5 12 X 1024 (negative) 663 EM-HI-, 633 [M-2CH3+H]-, data matrix using CH coupling of 135 Hz and a relaxation delay of 1.5 sec. The data matrix was 533; eims (aglycone) mlz 488 IM-CH,] , 470 processed using a q sine window function. In the [M-CH,-H,O]+, 452, 354, 268 [M-sidechain- H,0]+, 25 3. case of the COLOC experiment, delays were Vernonioside A, was washed from the coladjusted to an average CH coupling of 6 Hz; the spectral data were recorded in a 256X 1024 data umn with 65% MeOH. This was further purified by a combination of reversed- and normal-phase matrix. The nmr spectra were run in CD,OD. liquid chromatography as described for compound Fabms were recorded using NBA as matrix, in both the negative- and positive-ion mode on a 1,usingasolventgradientof60-75% MeOHand Finnigan-MAT 95 instrument. Eims were reisocratically in CHCIj-CH,OH-H,O (65:15:1), respectively,as eluting solvents. The pure fraction corded with the same instrument operating at an ionization energy of 70 eV. TICwas carried out on was evaporated to dryness in vacuo, precipitated Si gel places (Merck), using CHC1,-CH,OHwith a small volume of a CH,OH-H,O (1:3) H,O (65:14:1, S,) for glycosides, and CHC1,mixture and lyophilized to afford a white amorCH,OH (95:5, S,) for aglycones; and on RP-18 phous powder (80 mg); R,0.38 (SI), 0.40 6,);uv A max (MeOH), 234,241,25 1 nm; lsims (NBA) using CH,OH-H,O (75:25, S,) for both glycornlz (positive) 629 [M-HI+, 467 [M-glc-H]+, sides and aglycones. Spots were visualized by spraying the tlcplates with Liebermann-Burchard 446 [M-glc-H,O-H]+, (negative) 629 reagent (CH,OH-(CH,CO),O-H,SO4, 5: 1:1). [M-HI-, 573 [M-H-CH,-C,HJ-, 531,513, 41 1; eims mlz (aglycone)468 [MI', 45 5,354 [MFLun u m m . - T h e leaves of Vernonia CH, - C,H,,O]+, 3 37 [M -CH, - C6H,,0 amygdafina were harvested fresh from a horriculH,O]', 269 [M-side-chain-H,Ol+ (calcd for tural garden in Ibadan, Nigeria, and were airC29H4005); the "C-nmr data were superimposable dried. The plant was botanically identified by Dr. with those reported for vernonioside A, (7). J. Lowe of the Botany Department, University of Cornpound 2 was eluted from the column Ibadan, Nigeria, and a voucher sample was deposwith 70% MeOH. It was also subjected to reited in the Department of Biochemistry, College versed- and normal-phase liquid chromatographic of Medicine, University of Ibadan, Nigeria. purification using a solvent gradient of 6 5 4 0 % MeOH, and CHCIj-CH,OH-H,O (65:14:1) as E x ~ ~ I o N ~ I s o ~ T I O N . - T h e d r iand ed eluting solvents, respectively. T h e purified fracpowdered leaves of V. amygubfina (600 g) were tion was taken to dryness, precipitated from a extracted exhaustively with 4 liters of MeOH and small volume of a CH,OH-H,O (3:1) mixture and evaporated to near dryness. The dark-brown resilyophilized to afford a white amorphous powder due obtained was macerated with 30% hot MeOH (245 mg);R,0.35 (SI),0.42(S,);uvAmax(MeOH), and centrifuged at 3,000 g for 20 min, to obtain a 234, 241, 251 nm; lsims (negative) mlz 677 clear orange-brown supernatant that was condensedinvacuoand thensubmitted toaC,,(25-40 [M-HI-, 633 [M-H-COCHJ-, 533, 515 [M-H -glcf-, 477,339,325; eims mlz 470 [MI+, pm,Merck)short-glasscolumn(5cmX5 cmi.d.). T h e column was washed with aqueous solvents 456[M-CH3]+,452 [M-H,O]+, 268 [M-sidechain-H,O)+ (calcd for C2&I4,O5);I3C-nmrdata, containing increasing amounts of MeOH from see Table 1; 'H nmr 6 1.03 (3H, s, Me-18), 0.68 30% to 100%. Compound 1 waseluted with 50% (3H,s,Me-19), l.lO(lH, m, H-20), 1.16(3H,d, MeOH and was further purified by reversed-phase

EXPERIMENTAL

September 19957

Igile et al. : Saponins from Vernonia

J=6.0Hz,Me-21), 1.45,1.46(3Heach,s,Me-26 and Me-27), 1.67 (3H, d,]=5.5 Hz, Me-291, 2.00, 2.35 (1H each, m, H,-22), 2.16 (3H, s, COCH,), 3.12 ( l H , q,)=5.5 Hz, H-28), 4.18 ( l H , brm, H-16),4.51 (1H,d,J=7.7 Hz, H-l), 5.28(1H, t,J=6.8 Hz,H-23), 5.50(1H, brs,H7), 5.63 ( l H , br d,J=6.0 Hz, H-11).

ENZYMATIC"DRoLi'sIs.-The three glycosides (compounds l,2, and vernonioside A,) were hydrolyzed with P-glucosidase (emulsin, Serva). Thus, a 20-mg sample of each glycoside was incubated with an equivalent amount of p-glucosidase at 32" for 7 days. Each hydrolysate was filtered through a sintered glass funnel and the filtrates were analyzed for sugars. The precipitates obtained were lyophilized and then extracted with hot CHCI,. The CHCI, extracts were purified first by normal-phase cc using Si gel for flash chromatography (40 p n , J.T. Baker, B.V. Deventer, Holland) followed by normal-phase hplc using a Si gel steel column (Si 60, 15-25 km, Merck). During the purification of the aglycone of compound 1,the column was eluted with a CHC1,CH,OH (99:l) mixture. The aglycone of compound 2 was purified using CHCI,-CH,OH(97:3) as the eluting solvent. Purification of the aglycone of vernonioside A, was carried out using CHC1,CH,OH (98:2) as the eluting solvent. Each purified aglycone fraction was taken to dryness under reduced pressure and recrystallized from pure MeOH. T h e crystals were each filtered off from their mother solutions and dried at 60" to afford white crystalline solids. ACKNOWLEDGMENTS

2.

3. 4. 5.

6.

7.

8.

9.

10.

11.

12.

The authors would like to thank the Institute of Soil Science and Plant Cultivation, Pulawy, Poland, for the fellowship given LO G.Z. 13. LITERATURE CITED 1.

J.D. Phillipson, C.W. Wright, G.C. Kirby, and D.C. Warhurst, Abstracts, International Symposium of the Phytochemical Society of Europe, Lausanne, Switzerland, 29 Sept.-lO Oct. 1993, p. L3 .

14.

1443

M.A. Huffman and M. Seifu, Primates, 30, 51 (1989). S.M. Kupchan, R.J. Hemingway, A. Karim, and 0. Werner,). Org. C h . , 34,3908 (1969). I. Ganjian, I. Kubo, and P. Fludzinski, Pbytwhistry, 22, 2525 (1983). H. Ohigashi, M. Jisaka, T. Takagaki, H. Nozaki, T. Tada, M.A. Huffman, T. Nishida, M. Kaji, and K. Koshimizu,Agric. Bid. C h . ,55, 1201 (1991). M. Jisaka, H. Ohigashi, T. Takagaki, H. Nozaki, T. Tada, M. Hirota, R. Irie, M.A. Huffman, T. Nishida, M. Kaji, and K. Koshimizu, Tetrahedron, 48, 625 (1992). M. Jisaka, H . Ohigashi, K. Takegawa, M. Hirota, R. Irie, M.A. Huffman, and K. Koshimizu, Phytochemistry, 3 4 , 409 (1993). C. Kamperdick, E. Breitmaier, and M.A. Radloff,J . Prakt. C h . ,334,425 (1992). G.O. Igile, M. Fafunso, A. Fasanmade, S. Burda, M. Jurzysta, and W. Oleszek, "Proc. Int. Eur. Food Tox. IV C o d " Olsztyn, Poland, 22-24 Sept. 1994, p. 394. H. Ohigashi, M.A. Huffman, D. Izutsu, K. Koshimizu, M. Kawanaka, H. Sugiyama, G.C. Kirby, D.C. Warhurst, D. Allen, C.W. Wright, J.D. Phillipson, P. Timon-David, F. Delmas, R. Elias, and G. Balansard,J. C h .Ecol., 20, 541 (1994). G.O. Igile, W. Oleszek, M. Jurzysta, S. Burda, M. Fafunso, and A. Fasanmade,). Agric. Fwd C h . ,42,2445 (1994). A.I. Scott, in: "InternationalSeriesofMonographs on Organic Chemistry, Vol. 7." Ed. by D.H.R. Barton and W . Doering, Pergamon Press, London, 1964, pp. 5 1and 389. D. Ponglux, S. Wongseripipatana, N. Aimi, N. Oya, H. Hosokawa, J. Haginiwa, and S. Sakai, C h .Pbam. Bull., 40,553 (1992). H.O. Kalinowski, S. Berger, and S. Braun, "Carbon-1 3 NMR Spectroscopy," John Wiley and Sons, New York, 1988, p. 264.

R e c e i d I I November I994